CN111645189A

CN111645189A - Cement mixing apparatus for building

Info

Publication number: CN111645189A
Application number: CN202010464772.6A
Authority: CN
Inventors: 董青武
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-28
Filing date: 2020-05-28
Publication date: 2020-09-11

Abstract

The invention relates to the field of buildings, in particular to cement mixing equipment for buildings. The sand screening can be realized; the lime powder and the water can be mixed; the mixing amount of the lime powder and the water can be adjusted according to actual conditions; the preparation of cement can be realized. Including sand screening assembly, the transition assembly, the lime powder assembly, the water injection assembly, mix the assembly, the link, the input motor, the input awl tooth, the transmission awl tooth, lime powder through the rectangle through-hole outflow with hold the water contact in the chamber, and then form lime water, an articulated column motion simultaneously, and then through the six closed slide bar motions of being driven of articulated connecting rod, and then open or closed intercommunication sleeve pipe two through closed slide bar one drive the closure plate, and then realize the time that control lime water flows out, change along with the time interval along with V type pole reciprocating motion simultaneously, make the quantity of lime water through two outflow of intercommunication sleeve pipe change, realize the regulation to cement mixing effect.

Description

Cement mixing apparatus for building

Technical Field

The invention relates to the field of buildings, in particular to cement mixing equipment for buildings.

Background

The cement mixing device for the building is a common device in the field of the building, but the common cement mixing device for the building has single function.

Disclosure of Invention

The invention aims to provide cement mixing equipment for buildings, which can realize screening of sand; the lime powder and the water can be mixed; the mixing amount of the lime powder and the water can be adjusted according to actual conditions; the preparation of cement can be realized.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a cement mixing apparatus for building, includes sand screening assembly, transition assembly, lime powder assembly, water injection assembly, mixes assembly, link, input motor, input awl tooth, transmission awl tooth, its characterized in that: the sand screening combination is connected with the mixing combination, the transition combination is connected with the sand screening combination, the lime powder combination, the water injection combination and the mixing combination, the connecting frame is connected with the mixing combination, the input motor is connected with the connecting frame, the input motor is connected with the input bevel gear, the input bevel gear is connected with the transmission bevel gear, and the transmission bevel gear is connected with the lime powder combination.

As a further optimization of the technical scheme, the invention relates to a cement mixing device for buildings, wherein a sand screening assembly comprises a screening outer frame, a first rectangular through hole, a second rectangular through hole, a first communicating pipe, a first connecting rod, a second connecting rod, a third connecting rod, a rectangular slider, a first oscillating rod, a first matching slider, a second oscillating rod, a first cross frame, a second cross frame, a first sieve plate, a second sieve plate, a first sieve mesh, a second sieve mesh, a first half gear, a second half gear, a first inner end clamp push spring and a first inner end clamp groove, the first rectangular through hole and the second rectangular through hole are arranged on the screening outer frame, the first communicating pipe is fixedly connected and communicated with the screening outer frame, the first connecting rod is hinged with the second connecting rod, the second connecting rod is hinged with the third connecting rod, the third connecting rod is hinged with the rectangular slider, the rectangular slider is slidably connected with the first oscillating rod, the, the inner end clamp I is connected with the rectangular slider in a sliding mode, the inner end clamp push spring I is arranged between the two inner end clamps I, the matching slider I and the matching slider II are fixedly connected with the swing rod I, the matching slider I and the matching slider II are connected with the swing rod II in a matching mode, the cross frame I and the cross frame II are connected with the screening outer frame in a sliding mode, the half gear I and the half gear II are respectively in meshing transmission with the cross frame I and the cross frame II, the screen plate I and the screen plate II are connected with the screening outer frame in a sliding mode, the cross frame I and the cross frame II are fixedly connected with the screen plate I and the screen plate II, the screen hole I and the screen hole II are respectively arranged on the screen plate I and the screen plate II, the half gear I and the half gear II are respectively fixedly connected with the swing rod II and the swing rod I.

As a further optimization of the technical scheme, the invention relates to a cement mixing device for buildings, which comprises a first conical gear shaft, a first conical gear, a second conical gear, a third conical gear, a first cam, a second cam, a V-shaped rod, a first pulley, a second pulley, a spherical clamping rod and a spherical clamping rod push spring, wherein the first conical gear shaft is fixedly connected with the first conical gear, the first conical gear is in meshing transmission with the second conical gear, the second conical gear is in meshing transmission with the third conical gear, the third conical gear is fixedly connected with the first cam, the first cam is in rotating fit connection with the second cam, the first pulley and the second pulley are in rotating connection with the V-shaped rod, the first pulley and the second pulley are in fit connection with the first cam and the second cam, the spherical clamping rod is in sliding connection with the second cam, the clamping rod is clamped with the first cam, the spherical clamping rod push spring is arranged between the clamping rod and the second cam, and the first conical gear shaft is fixedly connected.

As a further optimization of the technical scheme, the lime powder combination body for the cement mixing equipment for the building comprises a lime powder outer frame, a first hinged connecting rod, a second hinged connecting rod, a third hinged connecting rod, a middle-end rectangular sliding block and a fourth hinged connecting rod, the middle-end sliding column, the middle-end sliding column push spring I, the middle-end sliding column push spring II, the oscillating plate and the rectangular through hole are hinged, the first hinge connecting rod is hinged with the second hinge connecting rod, the first hinge connecting rod is hinged with the third hinge connecting rod, the third hinge connecting rod is fixedly connected with the middle-end rectangular sliding block, the middle-end rectangular sliding block is slidably connected with the middle-end sliding column, the first middle-end sliding column push spring I and the second middle-end sliding column push spring II are connected with the middle-end sliding column in a sleeved mode, the middle-end sliding column is fixedly connected with the ash powder outer frame, the fourth hinge connecting rod is hinged with the middle-end rectangular sliding block, the fourth hinge connecting rod is hinged with the oscillating plate, the oscillating plate is rotatably connected with the lime powder outer frame, and the.

As a further optimization of the technical scheme, the invention relates to cement mixing equipment for buildings, wherein a water injection assembly comprises a containing cavity, a first water injection sleeve, a second water injection sleeve, a first hinge column, a sixth hinge connecting rod, a first closing slide rod, a second communicating sleeve, a middle-end filter plate, a filter hole, a first filter plate spring, a second filter plate spring, a closing plate and a closing plate spring, wherein the first water injection sleeve and the second water injection sleeve are fixedly connected and communicated with the containing cavity, the first hinge column is rotatably connected with the sixth hinge connecting rod, the sixth hinge connecting rod is rotatably connected with the first closing slide rod, the first closing slide rod is fixedly connected with the closing plate, the closing plate is slidably connected with the second communicating sleeve, the closing plate spring is connected with the first closing slide rod in a sleeved mode, the closing plate spring is arranged between the closing plate and the second communicating sleeve, the first filter plate spring and the second filter plate spring are connected with the containing cavity in a sleeved mode, the first filter plate spring and the second filter plate spring are respectively arranged at two ends of the middle-end filter plate, the filter holes are formed in the middle-end filter plate, the first hinge column is rotatably connected with the V-shaped rod, and the lime powder outer frame is fixedly connected with and communicated with the containing cavity.

As a further optimization of the technical scheme, the invention relates to cement mixing equipment for buildings, which comprises a mixing outer frame, a first communicating hole, a first inner rotating column, a first support rod, a second support rod, a third support rod, a second communicating hole, a first stirring blade, a first driving bevel gear, a second driving bevel gear, a third driving bevel gear, a second stirring blade, a discharge hole and a fourth driving bevel gear, wherein the first communicating hole and the second communicating hole are arranged on the mixing outer frame, the first support rod, the second support rod and the third support rod are fixedly connected with the mixing outer frame, the first inner rotating column is rotatably connected with the mixing outer frame, the first stirring blade is fixedly connected with the first inner rotating column, the first driving bevel gear is fixedly connected with the first inner rotating column, the second driving bevel gear and the fourth driving bevel gear are rotatably connected with the mixing outer frame, the second driving bevel gear and the fourth driving bevel gear are in meshing transmission with the first driving bevel gear and the third driving bevel gear is rotatably matched and connected with the first inner rotating column, the driving bevel gear III is fixedly connected with the stirring blade II, the discharge port is arranged on the mixed outer frame, the communicating hole I is fixedly connected and communicated with the communicating pipe I, the communicating sleeve II is fixedly connected and communicated with the communicating hole II, the support rod I, the support rod II and the support rod III are respectively connected with the V-shaped rod, the bevel gear shaft I and the bevel gear III in a rotating mode, the bevel gear II is fixedly connected with the inner rotating column I, the connecting frame is fixedly connected with the mixed outer frame, the input motor is fixedly connected with the connecting frame, the input motor is fixedly connected with the input bevel gear, the input bevel gear is in meshing transmission with the transmission bevel gear, and the transmission bevel gear is fixedly connected with the inner rotating column I.

The cement mixing equipment for the building has the beneficial effects that:

the invention relates to a cement mixing device for buildings, which is characterized in that a first water injection sleeve is simultaneously sleeved with a first water injection sleeve; the water is injected into the water injection sleeve pipe II, simultaneously under the action of water gravity, so that the water flows out along the communicating sleeve pipe II, simultaneously, lime powder flowing out through the rectangular through hole is in contact with water in the accommodating cavity, so that lime water is formed, simultaneously, the hinged column I moves, further, the hinged connecting rod II drives the closed sliding rod I to move, further, the closed plate is driven by the closed sliding rod I to open or close the communicating sleeve pipe II, further, the time for controlling the lime water to flow out is realized, simultaneously, the time interval along with the reciprocating motion of the V-shaped rod changes, further, the amount of the lime water flowing out through the communicating sleeve pipe II changes, and further, the regulation on the cement mixing effect is realized.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic illustration of the sand screening assembly of the present invention;

FIG. 4 is a second schematic illustration of the sand screening assembly of the present invention;

FIG. 5 is a third schematic illustration of the sand screening assembly of the present invention;

FIG. 6 is a first schematic view of a transition assembly according to the present invention;

FIG. 7 is a second schematic view of the transition assembly of the present invention;

FIG. 8 is a first schematic structural diagram of a lime powder assembly of the present invention;

FIG. 9 is a schematic structural diagram II of a lime powder combination of the present invention;

FIG. 10 is a first schematic view of the water injection assembly of the present invention;

FIG. 11 is a schematic structural diagram of a water injection assembly of the present invention;

FIG. 12 is a schematic view of a water injection assembly according to the present invention;

FIG. 13 is a first schematic structural diagram of a hybrid assembly of the present invention;

fig. 14 is a schematic structural diagram of the hybrid assembly of the present invention.

In the figure: a sand screening assembly 1; screening the outer frame 1-1; 1-2 of a rectangular through hole; a second rectangular through hole 1-3; 1-4 of a communicating pipe; 1-5 of a connecting rod I; a second connecting rod 1-6; connecting rods III 1-7; 1-8 of rectangular sliders; 1-9 parts of a first swing rod; 1-10 of a first matching slider; 1-11 of a second matching slider; 1-12 parts of a second swing rod; 1-13 of a transverse frame; a second transverse frame 1-14; 1-15 parts of a sieve plate I; a second sieve plate 1-16; 1-17 of sieve pores; 1-18 sieve holes II; 1-19 of a half gear; 1-20 parts of a half gear II; inner end clips 1-21; the inner end is clamped with a push spring 1-22; a first clamping groove 1-23 at the inner end; a transition assembly 2; 2-1 of a bevel gear shaft; 2-2 parts of a first bevel gear; 2-3 parts of a second bevel gear; 2-4 parts of bevel gear III; 2-5 parts of a cam I; 2-6 parts of a second cam; 2-7 of a V-shaped rod; 2-8 of a first pulley; 2-9 parts of a second pulley; 2-10 parts of a spherical clamping rod; 2-11 parts of a spherical clamping rod push spring; a lime powder combination 3; 3-1 parts of lime powder outer frame; 3-2 of a first hinged connecting rod; a second hinge connecting rod 3-3; 3-4 parts of a hinged connecting rod III; 3-5 of a middle-end rectangular sliding block; 3-6 parts of hinged connecting rod IV; 3-7 of a middle sliding column; a middle sliding column push spring I is 3-8; a middle sliding column pushing spring II 3-9; 3-10 of a vibrating plate; 3-11 rectangular through holes; a water injection assembly 4; the accommodating cavity 4-1; 4-2 of a water injection sleeve; 4-3 of a water injection sleeve; 4-4 parts of a hinge column I; six hinged connecting rods 4-5; closing the first sliding rod 4-6; a second communication sleeve 4-7; 4-8 parts of a middle-end filter plate; 4-9 of filter holes; 4-10 parts of a filter plate spring; 4-11 parts of a second filter plate spring; a closure panel 4-12; closing leaf springs 4-13; a mixing assembly 5; 5-1 part of a mixing outer frame; a communicating hole I5-2; 5-3 of an inner end rotating column; 5-4 parts of a first support rod; 5-5 parts of a second support rod; 5-6 parts of a support rod III; communicating holes II 5-7; 5-8 parts of a first stirring blade; 5-9 parts of a driving bevel gear I; 5-10 parts of a second driving bevel gear; 5-11 parts of driving bevel gear III; 5-12 parts of a second stirring blade; 5-13 parts of a discharge port; driving the four bevel gears 5-14; a connecting frame 6; an input motor 7; an input bevel gear 8; the bevel gear 9 is driven.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 14, and a cement mixing device for a building includes a sand screening assembly 1, a transition assembly 2, a lime powder assembly 3, a water injection assembly 4, a mixing assembly 5, a connecting frame 6, an input motor 7, an input bevel gear 8, and a transmission bevel gear 9, and is characterized in that: the sand screening combination 1 is connected with the mixing combination 5, the transition combination 2 is connected with the sand screening combination 1, the lime powder combination 3, the water injection combination 4 and the mixing combination 5, the connecting frame 6 is connected with the mixing combination 5, the input motor 7 is connected with the connecting frame 6, the input motor 7 is connected with the input bevel gear 8, the input bevel gear 8 is connected with the transmission bevel gear 9, and the transmission bevel gear 9 is connected with the lime powder combination 3.

The second embodiment is as follows:

the sand screening assembly 1 comprises a screening outer frame 1-1, a rectangular through hole I1-2, a rectangular through hole II 1-3, a communicating pipe I1-4, a connecting rod I1-5, a connecting rod II 1-6, a connecting rod III 1-7, a rectangular slider 1-8, a swing rod I1-9, a matching slider I1-10, a matching slider II 1-11, a swing rod II 1-12, a cross frame I1-13, a cross frame II 1-14, a sieve plate I1-15, a sieve plate II 1-16, a sieve hole I1-17, a sieve hole II 1-18, a half gear I1-19, a half gear II 1-20, an inner end clamp I1-21, an inner end clamp push spring I1-22, The inner end clamping groove I1-23, the rectangular through hole I1-2 and the rectangular through hole II 1-3 are arranged on the screening outer frame 1-1, the communicating pipe I1-4 is fixedly connected and communicated with the screening outer frame 1-1, the connecting rod I1-5 is hinged with the connecting rod II 1-6, the connecting rod II 1-6 is hinged with the connecting rod III 1-7, the connecting rod III 1-7 is hinged with the rectangular slider 1-8, the rectangular slider 1-8 is slidably connected with the swing rod I1-9, the inner end clamping groove I1-23 is arranged on the swing rod I1-9, the inner end clamp I1-21 is matched and connected with the inner end clamping groove I1-23, the inner end clamp I1-21 is slidably connected with the rectangular slider 1-8, the inner end clamp push spring I1-22 is arranged between the two inner end clamps I1-21, the first matched slider 1-10 and the second matched slider 1-11 are fixedly connected with the first swing rod 1-9, the first matched slider 1-10 and the second matched slider 1-11 are respectively connected with the second swing rod 1-12, the first cross frame 1-13 and the second cross frame 1-14 are slidably connected with the outer screening frame 1-1, the first half gear 1-19 and the second half gear 1-20 are respectively engaged with the first cross frame 1-13 and the second cross frame 1-14 for transmission, the first screen plate 1-15 and the second screen plate 1-16 are slidably connected with the outer screening frame 1-1, the first cross frame 1-13 and the second cross frame 1-14 are fixedly connected with the first screen plate 1-15 and the second screen plate 1-16, the first screen hole 1-17 and the second screen hole 1-18 are respectively arranged on the first screen plate 1-15 and the second screen plate 1-16, the half gear I1-19 and the half gear II 1-20 are respectively fixedly connected with the swing rod II 1-12 and the swing rod I1-9, and the swing rod II 1-12 and the swing rod I1-9 are rotatably connected with the screening outer frame 1-1.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the embodiment further describes the first embodiment, where the transition combination 2 includes a first conical tooth shaft 2-1, a first conical tooth 2-2, a second conical tooth 2-3, a third conical tooth 2-4, a first cam 2-5, a second cam 2-6, a V-shaped rod 2-7, a first pulley 2-8, a second pulley 2-9, a spherical clamping rod 2-10, and a spherical clamping rod push spring 2-11, the first conical tooth shaft 2-1 is fixedly connected with the first conical tooth 2-2, the first conical tooth 2-2 is in meshing transmission with the second conical tooth 2-3, the second conical tooth 2-3 is in meshing transmission with the third conical tooth 2-4, the third conical tooth 2-4 is fixedly connected with the first cam 2-5, the first cam 2-5 is in rotating fit connection with the second cam 2-6, the first pulley 2-8 and the second pulley 2-9 are rotatably connected with the V-shaped rod 2-7, the first pulley 2-8 and the second pulley 2-9 are in matched connection with the first cam 2-5 and the second cam 2-6, the spherical clamping rod 2-10 is in sliding connection with the second cam 2-6, the clamping rod 2-10 is clamped with the first cam 2-5, the spherical clamping rod push spring 2-11 is arranged between the clamping rod 2-10 and the second cam 2-6, and the first conical tooth shaft 2-1 is fixedly connected with the first connecting rod 1-5.

The fourth concrete implementation mode:

the lime powder combination 3 comprises a lime powder outer frame 3-1, a first hinged connecting rod 3-2, a second hinged connecting rod 3-3, a third hinged connecting rod 3-4, a middle-end rectangular sliding block 3-5, a fourth hinged connecting rod 3-6, a middle-end sliding column 3-7, a first middle-end sliding column push spring 3-8, a second middle-end sliding column push spring 3-9, a vibrating plate 3-10 and a rectangular through hole 3-11, wherein the first hinged connecting rod 3-2 is hinged with the second hinged connecting rod 3-3, the first hinged connecting rod 3-2 is hinged with the third hinged connecting rod 3-4, the third hinged connecting rod 3-4 is fixedly connected with the middle-end rectangular sliding block 3-5, the middle-end rectangular sliding block 3-5 is slidably connected with the middle-end sliding column 3-7, the middle-end sliding column push spring I3-8, the middle-end sliding column push spring II 3-9 and the middle-end sliding column 3-7 are connected in a sleeved mode, the middle-end sliding column 3-7 is fixedly connected with the lime powder outer frame 3-1, the hinged connecting rod IV 3-6 is hinged to the middle-end rectangular sliding block 3-5, the hinged connecting rod IV 3-6 is hinged to the vibrating plate 3-10, the vibrating plate 3-10 is rotatably connected with the lime powder outer frame 3-1, and the hinged connecting rod II 3-3 is rotatably connected with the pulley I2-8.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the embodiment further describes the first embodiment, wherein the water injection assembly 4 comprises a containing cavity 4-1, a first water injection sleeve 4-2, a second water injection sleeve 4-3, a first hinge column 4-4, a sixth hinge connecting rod 4-5, a first closing slide rod 4-6, a second communication sleeve 4-7, a middle filter plate 4-8, filter holes 4-9, a first filter plate spring 4-10, a second filter plate spring 4-11, a closing plate 4-12, a closing plate spring 4-13, a first water injection sleeve 4-2, a second water injection sleeve 4-3 and a containing cavity 4-1 which are fixedly connected and communicated, a first hinge column 4-4 is rotatably connected with a sixth hinge connecting rod 4-5, a sixth hinge connecting rod 4-5 is rotatably connected with a first closing slide rod 4-6, a first closing slide rod 4-6 is fixedly connected with a first closing plate 4-12, the second closing plate 4-12 is slidably connected with a second communicating sleeve 4-7, a first closing plate spring 4-13 is connected with the first closing slide rod 4-6 in a sleeved mode, a second closing plate spring 4-13 is arranged between the second closing plate 4-12 and the second communicating sleeve 4-7, a first filter plate spring 4-10 and a second filter plate spring 4-11 are connected with a containing cavity 4-1 in a sleeved mode, a middle-end filter plate 4-8 is slidably connected with the containing cavity 4-1, and the first filter plate spring 4-10, a second filter plate spring 4-11 is respectively arranged at two ends of the middle filter plate 4-8, a filter hole 4-9 is arranged on the middle filter plate 4-8, a first hinged column 4-4 is rotatably connected with a V-shaped rod 2-7, and a lime powder outer frame 3-1 is fixedly connected and communicated with a containing cavity 4-1;

4-2 of a water injection sleeve; the second water injection sleeve 4-3 is injected with water, and the water flows out along the second communication sleeve 4-7 under the action of the gravity of the water, meanwhile, the lime powder flowing out through the rectangular through hole 3-11 is contacted with the water in the containing cavity 4-1, thereby forming lime water, simultaneously moving the first hinged column 4-4, further driving the first closing slide rod 4-6 to move through the six hinged connecting rods 4-5, further drives the closing plate 4-12 to open or close the communicating sleeve 4-7 through the closing slide bar I4-6, thereby realizing the control of the lime water outflow time and simultaneously changing along with the time interval of the reciprocating motion of the V-shaped rods 2-7, and then the amount of the lime water flowing out through the second communication sleeve 4-7 is changed, and the adjustment of the cement mixing effect is further realized.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the embodiment further describes the first embodiment, the mixing assembly 5 includes a mixing outer frame 5-1, a communication hole one 5-2, an inner end rotating column one 5-3, a support rod one 5-4, a support rod two 5-5, a support rod three 5-6, a communication hole two 5-7, a stirring blade one 5-8, a driving bevel gear one 5-9, a driving bevel gear two 5-10, a driving bevel gear three 5-11, a stirring blade two 5-12, a discharge hole 5-13, a driving bevel gear four 5-14, the communication hole one 5-2 and the communication hole two 5-7 are all arranged on the mixing outer frame 5-1, the support rod one 5-4, the support rod two 5-5, and the support rod three 5-6 are fixedly connected with the mixing outer frame 5-1, an inner end rotating column I5-3 is rotationally connected with a mixing outer frame 5-1, a stirring blade I5-8 is fixedly connected with the inner end rotating column I5-3, a driving bevel gear I5-9 is fixedly connected with the inner end rotating column I5-3, a driving bevel gear II 5-10 and a driving bevel gear IV 5-14 are rotationally connected with the mixing outer frame 5-1, a driving bevel gear II 5-10 and a driving bevel gear IV 5-14 are in meshing transmission with the driving bevel gear I5-9 and the driving bevel gear III 5-11, the driving bevel gear III 5-11 is rotationally matched and connected with the inner end rotating column I5-3, the driving bevel gear III 5-11 is fixedly connected with the stirring blade II 5-12, a discharge port 5-13 is arranged on the mixing outer frame 5-1, a communicating hole I5-2 is fixedly connected and communicated with a communicating pipe I1-4, the communicating sleeve II 4-7 is fixedly connected and communicated with the communicating hole II 5-7, the support rod I5-4, the support rod II 5-5 and the support rod III 5-6 are respectively in rotating connection with the V-shaped rod 2-7, the bevel gear shaft I2-1 and the bevel gear III 2-4, the bevel gear II 2-3 is fixedly connected with the inner end rotating column I5-3, the connecting frame 6 is fixedly connected with the mixing outer frame 5-1, the input motor 7 is fixedly connected with the connecting frame 6, the input motor 7 is fixedly connected with the input bevel gear 8, the input bevel gear 8 is in meshing transmission with the transmission bevel gear 9, and the transmission bevel gear 9 is fixedly connected with the inner end rotating column I5-3.

The invention relates to a cement mixing device for buildings, which has the working principle that:

when the screening device is used, a screen to be screened is poured into the screening outer frame 1-1, the connecting rod I1-5 rotates at the same time, the connecting rod II 1-6 is driven to move, the connecting rod III 1-7 is driven to move, the rectangular slider 1-8 is driven to move, the inner end clips I1-21 are connected with the inner end clamping grooves I1-23 in a matching mode, the swing rod I1-9 is driven to move, and the matching slider I1-10 is driven; the second swing rod 1-12 is driven to move by matching with the second slider 1-11, and then passes through the first half gear 1-19 respectively; the half gear II 1-20 drives the sieve plate I1-15; the second sieve plate 1-16 moves and then passes through the first sieve plate 1-15; the second sieve plate 1-16 is in contact with the sieve, so that sand is sieved, qualified sand grains flow out through the first communicating pipe 1-4, and unsuitable sand grains flow through the first rectangular through hole 1-2; removing the rectangular through holes II 1-3; the screening speed of sand can be adjusted according to actual conditions, the rectangular sliders 1-8 slide along the first swing rods 1-9, so that the using positions of the rectangular sliders 1-8 on the first swing rods 1-9 are changed, the swing amplitudes of the first swing rods 1-9 are changed, and the first sieve plates 1-15 are driven by the transmission relationship; the reciprocating swing amplitude of the second sieve plate 1-16 changes, and then the first sieve plate 1-15 is realized; the speed of screening sand by the second screen plate 1-16 changes; the bevel gear II 2-3 rotates, the bevel gear shaft I2-1 is driven to rotate through the bevel gear I2-2, the connecting rod I1-5 is driven to rotate, and the cam I2-5 is driven through the bevel gear III 2-4; the cams 2-6 rotate simultaneously and then pass through the pulleys 2-8; the second pulley 2-9 drives the V-shaped rod 2-7 to rotate in a reciprocating mode, meanwhile, the second cam 2-6 is manually rotated, the second cam 2-6 and the first cam 2-5 are rotated relatively, and then the first pulley 2-8 is driven; the movement time of the pulley II 2-9 between the cam II 2-6 and the cam I2-5 is changed, so that the time interval of the reciprocating movement of the V-shaped rod 2-7 is changed, and further the further function adjustment is facilitated; putting lime powder into a lime powder outer frame 3-1, enabling a V-shaped rod 2-7 to reciprocate, further driving a first hinge connecting rod 3-2 to move through a second hinge connecting rod 3-3, further driving a third hinge connecting rod 3-4 to move through the first hinge connecting rod 3-2, further driving a middle-end rectangular sliding block 3-5 to reciprocate up and down along a middle-end sliding column 3-7 through the third hinge connecting rod 3-4, further driving a vibrating plate 3-10 to move through a fourth hinge connecting rod 3-6, further enabling the lime powder to flow out through a rectangular through hole 3-11 through the contact of the vibrating plate 3-10 and the lime powder, and simultaneously enabling the amount of the lime powder flowing out of the rectangular through hole 3-11 to change along with the change of the time interval of the reciprocating motion of the V-shaped rod 2-7; 4-2 of a water injection sleeve; the second water injection sleeve 4-3 is injected with water, and the water flows out along the second communication sleeve 4-7 under the action of the gravity of the water, meanwhile, the lime powder flowing out through the rectangular through hole 3-11 is contacted with the water in the containing cavity 4-1, thereby forming lime water, simultaneously moving the first hinged column 4-4, further driving the first closing slide rod 4-6 to move through the six hinged connecting rods 4-5, further drives the closing plate 4-12 to open or close the communicating sleeve 4-7 through the closing slide bar I4-6, thereby realizing the control of the lime water outflow time and simultaneously changing along with the time interval of the reciprocating motion of the V-shaped rods 2-7, the amount of the lime water flowing out through the second communication sleeve 4-7 is changed, and the cement mixing effect is adjusted; simultaneously starting the input motor 7, driving the input bevel gear 8 to move through the input motor 7, driving the inner end rotating post I5-3 to rotate through the transmission bevel gear 9, driving the bevel gear II 2-3 to rotate, simultaneously driving the driving bevel gear I5-9 to rotate, and further driving the bevel gear II 5-10; the driving bevel gear IV 5-14 drives the driving bevel gear III 5-11 to rotate, so that the stirring blades I5-8 are respectively driven; 5-12 of the second stirring blade rotates, and 5-8 of the first stirring blade passes through at the same time; (ii) a And 5-12 parts of a second stirring blade is mixed with sand and lime water, so that the preparation of cement is realized.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a cement mixing apparatus for building, includes sand screening combination (1), transition combination (2), lime powder combination (3), water injection combination (4), mixes combination (5), link (6), input motor (7), input awl tooth (8), transmission awl tooth (9), its characterized in that: the sand screening combination body (1) is connected with the mixing combination body (5), the transition combination body (2) is connected with the sand screening combination body (1), the lime powder combination body (3), the water injection combination body (4) and the mixing combination body (5), the connecting frame (6) is connected with the mixing combination body (5), the input motor (7) is connected with the connecting frame (6), the input motor (7) is connected with the input bevel gear (8), the input bevel gear (8) is connected with the transmission bevel gear (9), and the transmission bevel gear (9) is connected with the lime powder combination body (3).

2. A construction cement mixing apparatus as claimed in claim 1, wherein: the sand screening assembly (1) comprises a screening outer frame (1-1), a rectangular through hole I (1-2), a rectangular through hole II (1-3), a communicating pipe I (1-4), a connecting rod I (1-5), a connecting rod II (1-6), a connecting rod III (1-7), a rectangular slider (1-8), a swing rod I (1-9), a matching slider I (1-10), a matching slider II (1-11), a swing rod II (1-12), a cross frame I (1-13), a cross frame II (1-14), a sieve plate I (1-15), a sieve plate II (1-16), a sieve mesh I (1-17), a sieve mesh II (1-18), a half gear I (1-19), a half gear II (1-20), an inner end clamp I (1-21) and a clamp II (1-21), An inner end clamp push spring I (1-22) and an inner end clamp groove I (1-23), wherein a rectangular through hole I (1-2) and a rectangular through hole II (1-3) are arranged on a screening outer frame (1-1), a communicating pipe I (1-4) is fixedly connected and communicated with the screening outer frame (1-1), a connecting rod I (1-5) is hinged with a connecting rod II (1-6), a connecting rod II (1-6) is hinged with a connecting rod III (1-7), a connecting rod III (1-7) is hinged with a rectangular slider (1-8), a rectangular slider (1-8) is slidably connected with a swing rod I (1-9), an inner end clamp groove I (1-23) is arranged on the swing rod I (1-9), and an inner end clamp I (1-21) is matched and connected with the inner end clamp groove I (1-23), inner end clips I (1-21) are connected with a rectangular slider (1-8) in a sliding manner, inner end clip push springs I (1-22) are arranged between the two inner end clips I (1-21), a matching slider I (1-10) and a matching slider II (1-11) are fixedly connected with a swing rod I (1-9), the matching slider I (1-10) and the matching slider II (1-11) are connected with a swing rod II (1-12) in a matching manner, a cross frame I (1-13) and a cross frame II (1-14) are connected with a screening outer frame (1-1) in a sliding manner, a half gear I (1-19) and a half gear II (1-20) are respectively meshed with the cross frame I (1-13) and the cross frame II (1-14) for transmission, a screen plate I (1-15) and a screen plate II (1-16) are connected with the screening outer frame (1-1) in a sliding manner, the first crossbearer (1-13) and the second crossbearer (1-14) are fixedly connected with the first sieve plate (1-15) and the second sieve plate (1-16), the first sieve mesh (1-17) and the second sieve mesh (1-18) are respectively arranged on the first sieve plate (1-15) and the second sieve plate (1-16), the first half gear (1-19) and the second half gear (1-20) are respectively fixedly connected with the second swing rod (1-12) and the first swing rod (1-9), and the second swing rod (1-12) and the first swing rod (1-9) are rotatably connected with the screening outer frame (1-1).

3. A construction cement mixing apparatus as claimed in claim 1, wherein: the transition combination body (2) comprises a first conical gear shaft (2-1), a first conical gear (2-2), a second conical gear (2-3), a third conical gear (2-4), a first cam (2-5), a second cam (2-6), a V-shaped rod (2-7), a first pulley (2-8), a second pulley (2-9), a spherical clamping rod (2-10) and a spherical clamping rod push spring (2-11), wherein the first conical gear shaft (2-1) is fixedly connected with the first conical gear (2-2), the first conical gear (2-2) is in meshing transmission with the second conical gear (2-3), the second conical gear (2-3) is in meshing transmission with the third conical gear (2-4), the third conical gear (2-4) is fixedly connected with the first cam (2-5), the first cam (2-5) is in rotating fit connection with the second cam (2-6), the first pulley (2-8) and the second pulley (2-9) are rotatably connected with the V-shaped rod (2-7), the first pulley (2-8) and the second pulley (2-9) are connected with the first cam (2-5) and the second cam (2-6) in a matching mode, the spherical clamping rod (2-10) is connected with the second cam (2-6) in a sliding mode, the clamping rod (2-10) is connected with the first cam (2-5) in a clamping mode, the spherical clamping rod push spring (2-11) is arranged between the clamping rod (2-10) and the second cam (2-6), and the first conical tooth shaft (2-1) is fixedly connected with the first connecting rod (1-5).

4. A construction cement mixing apparatus as claimed in claim 1, wherein: the lime powder combination body (3) comprises a lime powder outer frame (3-1), a first hinged connecting rod (3-2), a second hinged connecting rod (3-3), a third hinged connecting rod (3-4), a middle-end rectangular sliding block (3-5), a fourth hinged connecting rod (3-6), a middle-end sliding column (3-7), a first middle-end sliding column push spring (3-8), a second middle-end sliding column push spring (3-9), an oscillating plate (3-10) and a rectangular through hole (3-11), the first hinged connecting rod (3-2) is hinged with the second hinged connecting rod (3-3), the first hinged connecting rod (3-2) is hinged with the third hinged connecting rod (3-4), the third hinged connecting rod (3-4) is fixedly connected with the middle-end rectangular sliding block (3-5), the middle-end rectangular sliding block (3-5) is slidably connected with the middle-end sliding column (3-7), the middle-end sliding column push spring I (3-8) and the middle-end sliding column push spring II (3-9) are connected with the middle-end sliding column (3-7) in a sleeved mode, the middle-end sliding column (3-7) is fixedly connected with the ash powder outer frame (3-1), the hinged connecting rod IV (3-6) is hinged with the middle-end rectangular sliding block (3-5), the hinged connecting rod IV (3-6) is hinged with the vibration plate (3-10), the vibration plate (3-10) is rotatably connected with the lime powder outer frame (3-1), and the hinged connecting rod II (3-3) is rotatably connected with the pulley I (2-8).

5. A construction cement mixing apparatus as claimed in claim 1, wherein: the water injection assembly (4) comprises a containing cavity (4-1), a first water injection sleeve (4-2), a second water injection sleeve (4-3), a first hinged column (4-4), a sixth hinged connecting rod (4-5), a first closed sliding rod (4-6), a second communicating sleeve (4-7), a middle-end filter plate (4-8), a filter hole (4-9), a first filter plate spring (4-10), a second filter plate spring (4-11), a closed plate (4-12) and a closed plate spring (4-13), wherein the first water injection sleeve (4-2), the second water injection sleeve (4-3) and the containing cavity (4-1) are fixedly connected and communicated, the first hinged column (4-4) is rotatably connected with a sixth hinged connecting rod (4-5), and the sixth hinged connecting rod (4-5) is rotatably connected with the first closed sliding rod (4-6), a first closing slide rod (4-6) is fixedly connected with a first closing plate (4-12), the closing plate (4-12) is connected with a second communicating sleeve (4-7) in a sliding manner, a first closing plate spring (4-13) is connected with the first closing slide rod (4-6) in a sleeved manner, the closing plate spring (4-13) is arranged between the closing plate (4-12) and the second communicating sleeve (4-7), a first filter plate spring (4-10) and a second filter plate spring (4-11) are connected with an accommodating cavity (4-1) in a sleeved manner, a middle-end filter plate (4-8) is connected with the accommodating cavity (4-1) in a sliding manner, the first filter plate spring (4-10) and the second filter plate spring (4-11) are respectively arranged at two ends of the middle-end filter plate (4-8), and filter holes (4-9) are arranged on the middle-end filter plate (4-8), the first hinged column (4-4) is rotatably connected with the V-shaped rod (2-7), and the lime powder outer frame (3-1) is fixedly connected and communicated with the accommodating cavity (4-1).

6. A construction cement mixing apparatus as claimed in claim 1, wherein: the mixing assembly (5) comprises a mixing outer frame (5-1), a first communicating hole (5-2), a first inner end rotating column (5-3), a first support rod (5-4), a second support rod (5-5), a third support rod (5-6), a second communicating hole (5-7), a first stirring blade (5-8), a first driving bevel gear (5-9), a second driving bevel gear (5-10), a third driving bevel gear (5-11), a second stirring blade (5-12), a discharge hole (5-13) and a fourth driving bevel gear (5-14), wherein the first communicating hole (5-2) and the second communicating hole (5-7) are arranged on the mixing outer frame (5-1), and the first support rod (5-4), the second support rod (5-5) and the third support rod (5-6) are fixedly connected with the mixing outer frame (5-1), an inner end rotating column I (5-3) is rotationally connected with a mixing outer frame (5-1), a stirring blade I (5-8) is fixedly connected with the inner end rotating column I (5-3), a driving bevel gear I (5-9) is fixedly connected with the inner end rotating column I (5-3), a driving bevel gear II (5-10) and a driving bevel gear IV (5-14) are rotationally connected with the mixing outer frame (5-1), the driving bevel gear II (5-10), the driving bevel gear IV (5-14) are in meshing transmission with the driving bevel gear I (5-9) and the driving bevel gear III (5-11), the driving bevel gear III (5-11) is rotationally matched and connected with the inner end rotating column I (5-3), the driving bevel gear III (5-11) is fixedly connected with the stirring blade II (5-12), a discharge port (5-13) is arranged on the mixing outer frame (5-1), the communicating hole I (5-2) is fixedly connected and communicated with the communicating pipe I (1-4), the communicating sleeve II (4-7) is fixedly connected and communicated with the communicating hole II (5-7), the support rod I (5-4), the support rod II (5-5) and the support rod III (5-6) are respectively connected with the V-shaped rod (2-7), the bevel gear shaft I (2-1) and the bevel gear III (2-4) are rotatably connected, the bevel gear II (2-3) is fixedly connected with the inner end rotating column I (5-3), the connecting frame (6) is fixedly connected with the mixing outer frame (5-1), the input motor (7) is fixedly connected with the connecting frame (6), the input motor (7) is fixedly connected with the input bevel gear (8), the input bevel gear (8) is in meshing transmission with the transmission bevel gear (9), and the transmission bevel gear (9) is fixedly connected with the inner end rotating column I (5-3).